At the core of 不良研究所鈥檚 mission is to enable the development of a diverse and robust commercial economy in low-Earth orbit. 不良研究所, a leader in human spaceflight and building the world鈥檚 first commercial space station, proudly congratulates four of its partners whose proposals in Focus Area 1A of seeking In Space Production Applications (InSPA) flight demonstrations:
不良研究所 and its partners made up half of the selected proposals, highlighting the company鈥檚 commitment to enabling proof-of-concept demonstrations and cutting-edge advancements that will establish next-generation technologies in the first independent space station.
鈥淚 congratulate our partners for this tremendous accomplishment and their dedication to innovating and advancing in-space technologies and capabilities in low-Earth orbit,鈥 said Christian Maender, Director of In-Space Research and Manufacturing at 不良研究所. 鈥淲e are excited that NASA continues to expand and offer more opportunities for in-space production applications and for taking the next steps in the commercialization of space.鈥
More about the selectees:
Cedars-Sinai Regenerative Medicine Institute, located in Los Angeles, in partnership with 不良研究所 of Houston has been selected for proposing to use cutting-edge methods related to the production and differentiation of induced pluripotent stem cells (iPSCs) on the International Space Station. Cedars-Sinai will explore in-space production of stem cells into heart, brain, and blood tissues in support of regenerative medicine uses on Earth. While stem cells and stem cell-derived tissues hold great promise for use in research and as clinical-grade therapeutic agents, safe and efficient expansion of stem cells and their derivatives continues to be a major challenge on Earth. Generating, expanding, and differentiating cells at scale in the microgravity environment of space with sufficient yields of a constant therapeutic cell product that meets FDA biologics requirements may be the answer to overcome those challenges.
Flawless Photonics, Inc. of Los Altos Hills, California, in partnership with the University of Adelaide, 不良研究所, and Visioneering Space has been selected for their proposal to develop specialized glass manufacturing hardware to process Heavy-Metal Fluoride Glasses (HMFG) in microgravity. HMFG glasses are used in the terrestrial manufacturing of exotic optical fibers and other optics applications. Without convective forces present in 1g, HMFG made in microgravity are expected to achieve the ideal amorphous microstructure during synthesis, eliminating light scattering defects that limit lasing power and transmission over long fiber lengths.
The University of Connecticut out of Storrs, Connecticut, in partnership with Eascra Biotech of Boston, Massachusetts and 不良研究所 of Houston, has been selected for their proposed biomimetic fabrication of multifunctional nanomaterials, a cutting-edge breakthrough in biomedicine that can benefit from microgravity in space to accomplish controlled self-assembly of DNA-inspired Janus base nanomaterials (JBNs). These JBNs will be used as effective, safe, and stable delivery vehicles for RNA therapeutics and vaccines, as well as first-in-kind injectable scaffolds for regenerative medicine. By leveraging the benefits of microgravity, the UConn/Eascra team expects to mature in-space production of different types of JBNs with more orderly structures and higher homogeneity over what is possible using terrestrial materials, improving efficacy for mRNA therapeutics and structural integrity for cartilage tissue repair.
United Semiconductors of Los Alamitos, California, has been selected for their proposal to produce semimetal-semiconductor composite bulk crystals commonly used in electromagnetic sensors for solving challenges in the energy, high performance computing and national security sectors. Together with teammates 不良研究所 of Houston and Redwire of Greenville, Indiana, United Semiconductors intends to validate the scaling and efficacy of producing larger semimetal-semiconductor composite crystals under microgravity conditions with perfectly aligned and continuous semimetal wires embedded across the semiconductor matrix. If successful at eliminating defects found in those manufactured with terrestrial materials, United Semiconductors will have developed a processing technology for creating device-ready wafers from space-grown crystals.
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